JP4403319B2 - Terminal device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention From the information center, the specified program is separated into summary data from which the overview of the entire program can be grasped and supplementary data that can be restored to the original program by combining with the above summary data, and delivered in the order of summary data and supplementary data Terminal device For example, it is suitably used in a data service system that distributes digital data.
[0002]
[Prior art]
A data transmission / reception system constructed between the user side and the server side has been proposed due to the development of data compression technology for video data and audio data and the development of digital signal processing technology in the broadcasting / communication field. . The data transmission / reception system is a service for distributing digital data called so-called VOD (Video On Demand) or MOD (Music On Demand). As an example of the data transmission / reception system, for example, a MOD system that transmits / receives data using the Internet and a packet transmission method has been proposed.
[0003]
[Problems to be solved by the invention]
However, in such a MOD system, it is often difficult to transmit digital data without delay due to transmission rate limitations and generation of interrupt data. For example, in a conventional MOD system, when music data is transferred from the data transmitting side to the data receiving side, for example, the transfer rate of the communication line and the data transfer rate necessary for real-time reproduction of the music data are close to each other. Often occurred. In such a case, if the data reception side tries to reproduce the music data simultaneously while downloading the music data to the hard disk or the like (hereinafter referred to as real-time reproduction), the audio data is transmitted because the transfer rates are adjacent to each other. There has been a problem that continuous playback of data cannot be realized, or that music data cannot be played back until the download is actually completed.
[0004]
Further, in the conventional MOD system, when music data is transferred from the data transmission side to the data reception side, for example, the maximum transfer rate of the communication line is 28.8 kbps, the average transfer rate is 22 kbps, and the music data is reproduced in real time. There was a case where the required data transfer rate was 32 kbps. In such a case, since the data transfer rate required for real-time reproduction exceeds the transfer rate of the communication line, there is a problem that the received data cannot be reproduced in real time on the receiving side.
[0005]
The present invention has been proposed in view of the above circumstances, and provides a distribution system, an information center, a terminal device, and a distribution method capable of avoiding a reproduction failure or the like in real-time reproduction at the time of data reception. Objective.
[0006]
[Means for Solving the Problems]
The present invention separates summary data / complementary data from an information center into summary data from which the designated program can grasp the summary of the entire program and supplementary data that can be restored to the original program by combining with the summary data. Terminal device distributed in the above order, receiving means for receiving summary data and supplementary data distributed from the information center, and synthesis for combining the summary data received by the receiving means and the complementary data And a reproducing means for performing monitor reproduction based on at least the summary data among the received separated data, The program comprises audio data, and the summary data and the complementary data distributed from the information center comprise an addition output of a plurality of channels of the audio data and a subtraction output of a plurality of channels of the audio data, The complementary data transmitted with the lock data added from the information center is received by the receiving means, and the key data corresponding to the received lock data is obtained by applying a predetermined charging process, The complementary data can be reproduced by collating the lock data with the key data, and the summary data and the complementary data can be reproduced by the synthesizing means. And the original signal by adding and subtracting It is characterized by restoring the original program.
[0007]
The present invention is also an information center that distributes a program to a terminal device, a storage unit that stores a plurality of programs, and a plurality of programs that are stored in the storage unit by a desired program selected by the terminal device. Retrieving the original program by synthesizing the summary data with the data retrieval means selected from the program, the summary data with which the outline of the entire program can be grasped, and the desired program selected by the data retrieval means Separating means for separating the data into possible complementary data, and transmission means for transmitting the summary data separated by the separating means and the complementary data in a time-sharing manner.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments to which the present invention is applied will be described in detail with reference to the drawings. The data transmission / reception system 1 shown in FIG. 1 to which the present invention is applied is a so-called music-on-demand system. The data transmission device 10 is a server-side terminal device and the data reception device is a user-side terminal device. The apparatus 20 is configured to be connected via a communication line 30 such as a telephone line. Here, the data transmission device 10 is provided in, for example, a data management center on the server side. On the other hand, the data receiving device 20 is installed in the home of each user for consumer use, for example. In FIG. 1, only one data receiving device 20 is shown for convenience, but actually, a plurality of data receiving devices 20 are connected to the server-side data transmitting device 10 via the communication line 30.
[0011]
The server-side data transmission device 10 receives the request information supplied from the user-side data reception device 20 via the communication line 30 and searches for the corresponding data based on the received request information. This is a device that separates summary data and complementary data by a predetermined method, and transfers the separated data to the data receiving device 20 via the communication line 30 in the order of summary data and complementary data.
[0012]
As shown in FIG. 1, the data transmission apparatus 10 is connected to a data reception apparatus 20 on the user side via a communication line 30 and stores data such as a music 11 and a modem 11 that transmits and receives data. A large-capacity hard disk array 12, a data search processing unit 13 for searching for the corresponding data from the hard disk array 12, and data searched by the data search processing unit 13 are separated into summary data and complementary data by a predetermined method. And a control unit 15 that controls the entire apparatus.
[0013]
The modem 11 is connected to the data receiving device 20 via the communication line 30, receives the request information transmitted from the data receiving device 20, and supplies the request information to the control unit 15. In addition, the modem 11 sequentially transmits outline data and complementary data output from the data separation unit 14, which will be described in detail later, to the data receiving device 20 side. Each operation of the modem 11 is executed based on a control signal from the control unit 15.
[0014]
The hard disk array 12 stores music data of various genres for realizing music on demand (MOD), music guide data for searching for desired music data, and other audio data.
[0015]
The data search processing unit 13 receives the request information from the data receiving device 20 received by the modem 11 via the control unit 15, and based on this request information, a lot of data such as music stored in the hard disk array 12. A search process is performed to search for the corresponding data from the list. Then, the data search processing unit 13 reads out the corresponding data from the hard disk array 12 and outputs it to the data separation unit 14. Each operation of the data search processing unit 13 is performed based on a control signal from the control unit 15.
[0016]
The data separation unit 14 performs separation processing for separating the data supplied from the data search processing unit 13 into outline data and complementary data by a predetermined method set in advance. The data separation unit 14 includes a memory for temporarily storing data. The data separated by the separation process first outputs summary data to the modem 11 and temporarily stores complementary data in the memory. Then, when the output of the summary data is completed, the data separation unit 14 reads the complementary data stored in the memory and outputs it to the modem 11. The above-described operations of the data separation unit are executed based on a control signal from the control unit 15.
[0017]
Here, specific examples of the method of separating the data into the summary data and the complementary data by the data separation unit 14 include the following various methods.
[0018]
That is, for example, as a first embodiment of a system for separating music data, summary data is L (left) channel audio data + R (right) channel audio data, and complementary data is L channel audio data-R channel. There is a method of using audio data.
[0019]
As a second embodiment of the music data separation system, in the case of modulation in the frequency domain, there is a system in which outline data is an even spectrum and complementary data is an odd spectrum. In this case, a method of changing the weight of each spectrum may be used.
[0020]
Further, as a third embodiment of the music data separation method, a method in which the outline data is data in the middle frequency region and the complementary data is in the low frequency and high frequency regions, or the outline data is in the low frequency range. There is a method in which region data is used and complementary data is data in a high frequency region.
[0021]
Furthermore, as a fourth embodiment of the music data separation system, there is a system in which the outline data is vocal data and the complementary data is so-called karaoke data.
[0022]
As described above, various methods as described above can be considered as a data separation method, and a preferable method can be selected as appropriate according to circumstances. As a data separation method, the ratio between the summary data and the complementary data is not necessarily 1: 1, that is, the data capacity after separation is not necessarily 50% to 50%.
[0023]
Here, as for the ratio between the summary data and the supplemental data, the higher the ratio of the summary data, the higher the quality of data reproduction becomes possible at the time of reproduction on the data receiving apparatus 20 side. In addition, there may be a case where the summary data cannot be reproduced in real time due to the relationship with the modem 21 or the like of the data receiving device 20. On the other hand, as the ratio of the summary data is reduced, the real-time reproduction on the data receiving device 20 side is performed smoothly. On the other hand, the quality of the audio reproduced during the real-time reproduction is lowered. Therefore, the data transmitting apparatus 10 may be separated into summary data and complementary data at an appropriate ratio in consideration of such a trade-off.
[0024]
As an embodiment of the present invention, compressed audio data is transferred from a data transmission device 10 which is a server side terminal device to a data reception device 20 which is a user side terminal device. Possible compression methods include ATRAC (Adapted transform acoustic coding) method, Twin-VQ (Transform domain Weighted Interleave Vector Quantization) method, Real Audio method, MPEG (Moving Picture Experts Group) Layer 2 method, etc. In the embodiment of the invention, the ATRAC method is adopted.
[0025]
Hereinafter, the ATRAC system will be described with reference to FIG.
[0026]
The audio compression circuit based on the ATRAC system realizes high-efficiency coding using subband coding (SBS), adaptive transform coding (ATC), and adaptive bit allocation techniques. Yes.
[0027]
In the specific high-efficiency encoding apparatus shown in FIG. 2, the input digital signal is divided into a plurality of frequency bands, and the signals are orthogonally transformed for each frequency band to be included in a plurality of two-dimensional blocks related to time and frequency. Obtaining new synthesized data for encoding and analysis, the obtained spectrum data of the frequency axis is divided into medium and high for each so-called critical band (critical band) considering human auditory characteristics described later in the low frequency range. In the band, bit allocation is adaptively allocated and coded for each band obtained by subdividing the critical bandwidth in consideration of block floating efficiency. Normally, this block is a quantization noise generation block. Further, in this specific example, the block size (block length) is adaptively changed according to the input signal before the orthogonal transformation.
[0028]
That is, in FIG. 2, an audio PCM signal obtained by sampling an audio signal of 0 to 22 kHz at 44.1 kHz and converting it into a digital signal and pulse-modulating the digital audio signal is input to the input terminal 100. Supplied as a signal. This input signal is divided into a signal in a band of 0 to 11 kHz and a signal in a band of 11 kHz to 22 kHz by a band division filter 101 such as a so-called QMF (Quadrature Mirror Filter). A signal in the band of 0 to 11 kHz is also divided into a signal in the band of 0 to 5.5 kHz and a signal in the band of 5.5 kHz to 11 kHz by the band division filter 102 such as QMF. A signal in the band of 11 kHz to 22 kHz from the band division filter 101 is sent to an MDCT (Modified Discrete Cosine Transform) circuit 103 which is an example of an orthogonal transform circuit. A signal in the band of 5.5 kHz to 11 kHz from the band division filter 102 is sent to the MDCT circuit 104, and a signal in the band of 0 to 5.5 kHz from the band division filter 102 is sent to the MDCT circuit 105, respectively. MDCT processed. Each MDCT circuit 103, 104, 105 performs MDCT processing based on the block size (information compression parameter) determined by the block determination circuits 109, 110, 111 provided for each band.
[0029]
Here, (A), (B), and (C) show examples of standard input signals for the blocks for each band supplied to the MDCT circuits 103, 104, and 105, respectively. In the example shown in FIG. 3, each of the three filter output signals has a plurality of orthogonal transform block sizes (information compression parameters) independently for each band, and the time resolution can be switched depending on the time characteristics, frequency distribution, etc. of the signal. I am doing so. When the signal is quasi-stationary in time, the orthogonal transform block size is increased to 11.6 ms, that is, the long mode in FIG. 3A, and the signal is non-stationary. In some cases, the orthogonal transform block size is further divided into two and four. As in the short mode (Short mode) in FIG. 3B, when all are set to 40% and 2.9 ms, the middle mode A (Middle Mode A) in FIG. In order to adapt to actual complex input signals, the resolution is partially divided into 2 parts, 5.8 ms, and partly divided into 4 parts and 2.9 ms, as in the middle mode B in FIG. It has become. This division of the orthogonal transform block size is obviously more effective if a more complicated division is performed if the scale of the processing device permits.
[0030]
The block size (information compression parameter) is determined by the block determination circuits 109, 110, and 111 in FIG. 2, and is transmitted to each MDCT circuit 103, 104, and 105 and the bit allocation calculation circuit 118 as block size information of the block. At the same time, it is output from the output terminals 113, 115 and 117.
[0031]
In FIG. 2 again, in the spectrum data or MDCT coefficient data (signal components in the two-dimensional block relating to time and frequency) obtained by the MDCT processing in each MDCT circuit 103, 104, 105, the low frequency is The middle and high bands are grouped into so-called critical bands, and in consideration of the effectiveness of block floating, the critical bandwidth is subdivided into adaptive bit allocation coding circuits 106, 107, 108 and bit allocation calculation circuit 118. Sent. This critical band is a frequency band that is divided in consideration of human auditory characteristics, and is a band of noise when the pure tone is masked by a narrow band noise of the same intensity near the frequency of a certain pure tone. That is. The critical band (critical band) has a wider bandwidth as the frequency is higher, and the entire frequency band of 0 to 22 kHz is divided into, for example, 25 critical bands.
[0032]
The bit allocation calculation circuit 118 in FIG. 2 takes into account the so-called masking effect and the like based on the block size information and spectrum data or MDCT coefficient data for each divided band considering the above critical band and block floating. The masking amount and the energy or peak value for each divided band are calculated, and the number of allocated bits (bit allocation amount) is obtained for each band based on the result, and the adaptive bit allocation encoding circuits 106, 107, 108.
[0033]
In these adaptive bit allocation coding circuits 106, 107, and 108, according to the above-described block size information and the number of bits allocated to each divided band considering the critical band and block floating, each spectrum data or MDCT The coefficient data is re-quantized (normalized and quantized). The data encoded in this way is taken out via the output terminals 112, 114, 116 in FIG. Hereinafter, for convenience of explanation, each divided band considering the above critical band and block floating, which is a unit of bit allocation, will be referred to as a unit block.
[0034]
The high-efficiency compression encoder described with reference to FIG. 2 is provided in the data separation unit 14 of FIG. 1 and performs compression processing on the digital audio signal transmitted from the data search processing unit 13 to divide the band. 2 is output as summary data and output from the adaptive bit allocation encoding circuit 106 and the adaptive bit allocation encoding circuit 108 of FIG. The low-frequency and high-frequency band compressed data is output as complementary data.
[0035]
Based on the request information from the data receiving device 20 sent via the communication line 30, the control unit 15 transmits the data such as music to the data receiving device 20 in a predetermined separation method. A control program is provided, and the modem 11, the data search processing unit 13, and the data separation unit 14 are controlled based on the transmission control program.
[0036]
Specifically, the control unit 15 receives the request information transmitted from the data receiving device 20 via the communication line 30 and controls the modem 11 to supply the received request information to the control unit 15. The control unit 15 temporarily stores the request information supplied from the modem 11 and supplies the request information to the data search processing unit 13. At this time, the control unit 15 may extract only the data designation information described later from the request information and supply it to the data search processing unit 13.
[0037]
In addition, the control unit 15 performs the above-described search process based on the data designation information in the request information, reads the retrieved data from the hard disk array 12, and outputs the data to the data separation unit 14. To control.
[0038]
Further, the control unit 15 performs the above-described separation process on the data supplied from the data search processing unit 13 according to a predetermined method set in advance, and outputs the separated summary data to the modem 11, and after the separation. The data separation unit 14 is controlled to store the complementary data in the memory. Then, the control unit 15 refers to user ID information described later in the request information, and controls the modem 11 so as to transmit the separated outline data supplied from the data separation unit 14 to the data receiving device 20 side. To do. Further, when the transmission of the summary data is completed, the control unit 15 reads the supplementary data from the memory of the data separation unit 14 and sets the data separation unit 14 and the modem 11 so as to transmit the supplemental data to the data receiving device 20 side. Control. As a result, in the data transmission / reception system 1, data is transferred from the data transmission device 10 to the data reception device 20 in the order of summary data and complementary data.
[0039]
On the other hand, the user-side data reception device 20 transmits request information to the server-side data transmission device 10 based on the user's request, and the above-described summary data transferred from the data transmission device 10 based on the request information and The supplementary data is sequentially received, the summary data is recorded and / or reproduced, and the summary data and the complement data are synthesized to generate synthesized data, and the synthesized data is recorded and / or reproduced. It is a device for.
[0040]
As shown in FIG. 1, the data receiving apparatus 20 is connected to the data transmitting apparatus 10 via a communication line 30 and stores a modem 21 for transmitting and receiving data, and the above summary data, complementary data, or synthesized data. A hard disk drive (HDD) 22, a data synthesis unit 23 for synthesizing the summary data and the complementary data, a reproduction processing unit 24 for performing a predetermined reproduction process on the data output from the data synthesis unit 23, An output unit 25 including a speaker, a monitor, a headphone jack, and the like (not shown), a control unit 26 that controls the entire apparatus, and an operation input unit 27 including a keyboard and a mouse (not shown) for giving instructions to the control unit 26 It is prepared for.
[0041]
The modem 21 is connected to the data transmission device 10 via the communication line 30 and transmits request information, which will be described later in detail, supplied from the control unit 26 to the data transmission device 10 side. Further, the modem 21 sequentially receives the outline data and the complementary data transferred from the data transmission device 10 based on the request information, and supplies the received data to the HDD 22 and the data synthesis unit 23. Each operation of the modem 21 is performed based on a control signal from the control unit 26.
[0042]
The HDD 22 includes a hard disk (not shown) for storing summary data, complementary data, or composite data, and can record the summary data and complementary data supplied from the modem 21 on the hard disk. Further, the HDD 22 is connected to the data synthesis unit 23, records the synthesis data to be described later in detail supplied from the data synthesis unit 23, and reads the recorded synthesis data or the recorded summary data or complementary data. The data composition unit 23 is supplied. Each operation of the HDD 22 is executed based on a control signal from the control unit 26.
[0043]
The data synthesis unit 23 corresponds to the data separation unit 14 of the data transmission device 10 described above, and includes a memory for temporarily storing data, as with the data separation unit 14. Based on the control signal from the control unit 26, the data synthesizing unit 23 performs the following processing on the summary data and the supplemental data transferred from the data transmission device 10 via the modem 21.
[0044]
The data synthesis unit 23 stores the summary data supplied from the modem 21 in the memory and supplies the summary data to the reproduction processing unit 24. Further, when supplementary data is supplied from the modem 21, the data synthesis unit 23 reads the summary data stored in the memory and performs a process of synthesizing it with the supplemental data to generate synthesized data, and the generated synthesized data Is output to the reproduction processing unit 24. In addition, when reproducing the summary data, the complementary data, or the synthesized data recorded on the hard disk of the HDD 22, the data synthesizing unit 23 outputs any of the data supplied from the HDD 22 to the reproduction processing unit 24 as it is. It is supposed to be.
[0045]
FIG. 4 shows a specific configuration of the data synthesizer 23 shown in FIG. FIG. 4 shows a decoding circuit (decoder) for decoding again a signal that has been highly efficient encoded by the system shown in FIG. The quantized MDCT coefficients of each band, that is, the data equivalent to the output signals of the output terminals 112, 114, and 116 in FIG. 2, are provided to the input terminal 207 in FIG. 4, and used block size information, that is, the output in FIG. Data equivalent to the output signals of the terminals 113, 115, and 117 is given to the input terminal 208 in FIG.
[0046]
The adaptive bit allocation decoding circuit 206 in FIG. 4 releases bit allocation using the adaptive bit allocation information. Next, in the inverse orthogonal transform (IDCT) circuits 203, 204, and 205 in FIG. 4, signals on the frequency axis are converted into signals on the time axis. The signals on the time axis of these partial bands are decoded into full-band signals by band synthesis filter (IQMF) circuits 202 and 201 in FIG. The signals synthesized by the band synthesis filter circuits 202 and 201 are output from the output terminal 200. The signal output from the output terminal 200 corresponds to the combined data output from the data combining unit 23 in FIG.
[0047]
Further, the decoding result of the compressed data in the middle band obtained by the inverse orthogonal transform circuit 204 is output as summary data via the output terminal 209. That is, the signal output from the output terminal 209 corresponds to the outline data output from the data synthesis unit 23 in FIG.
[0048]
Further, in the first embodiment in which L (left) channel + R (right) channel is used as summary data and L (left) channel-R (right) channel is used as complementary data,
(Summary data + complementary data) ÷ 2 = L (left) channel
(Summary data-complementary data) ÷ 2 = R (right) channel
Thus, the L (left) channel and the R (right) channel can be restored.
[0049]
In the processing of the data synthesizing unit 23 in the second embodiment, it is possible to restore the synthesized data by alternately arranging the even spectrum as the outline data and the odd spectrum as the complementary data. Further, the outline data is reproduced by generating an odd spectrum by performing interpolation using the even spectrum and outputting it as outline data.
[0050]
The third embodiment is as described above.
[0051]
Furthermore, in the fourth embodiment, the synthesized data can be restored by synthesizing and reproducing the vocal part that is summary data and the karaoke part that is complementary data.
[0052]
Based on the control signal from the control unit 26, the reproduction processing unit 24 performs predetermined processing such as decompression processing, D / A conversion processing, amplification processing, etc. on the summary data, complementary data, or composite data supplied from the data synthesis unit 23. The analog reproduction signal is generated by applying the reproduction signal to the speaker and the headphone jack of the output unit 25. Thereby, in the data reception device 20, an audio signal is output from the speaker of the output unit 25.
[0053]
The control unit 26 is configured by, for example, a personal computer. The control unit 26 includes a control program for acquiring data such as the music from the data transmission device 10 via the communication line 30. By executing the control program, the modem 21, the HDD 22, and the data synthesis unit 23, the reproduction processing unit 24 and the monitor of the output unit 25 are controlled. The control unit 26 is connected to the operation input unit 27, and performs each control in the control program based on an operation input signal input by operating the keyboard and mouse of the operation input unit 27.
[0054]
Specifically, the control unit 26 transmits the information on the data name such as the genre name, the player name, and the title name regarding the data such as music that the user desires to the data transmitting apparatus 10 as the data designation information. 21 is controlled.
[0055]
In addition, the control unit 26 controls the modem 21 so as to transmit information about a user ID for identifying the user (hereinafter referred to as user ID information) to the data transmitting apparatus 10. Specifically, the control unit 26 registers the user ID in advance in the initial setting of the control program, and transmits the data designation information and the user ID information together as request information to the data transmission device 10 at once. The modem 21 is controlled as follows.
[0056]
After starting the control program, for example, by operating the keyboard or mouse of the operation input unit 27 by a so-called GUI (Graphical User Interface) method, the user is sent to the control unit 26 via the monitor of the output unit 25. What is necessary is just to perform registration about ID and the input of the said data name. Then, the control unit 26 generates user ID information and data designation information from these user IDs and data names, and controls the modem 21 so as to transmit them as request information to the data transmission device 10 at once.
[0057]
Further, the control unit 26 performs the reproduction process, the recording process to the hard disk, the outline data, and the supplementary data as described above for the outline data and the supplementary data sequentially transferred from the data transmitting apparatus 10 after the transmission of the request information. The modem 21, the HDD 22, the data synthesis unit 23, and the reproduction processing unit 24 are controlled so as to perform the synthesis process. Thus, in the data receiving device 20, the outline data about the received audio data is output from the speaker of the output unit 25 in real time, and the audio data can be continuously played back. Although the sound quality is not satisfactory, it can be downloaded. You can monitor the songs you have.
[0058]
In the data transmission / reception system 1, when music data is transferred from the data transmission device 10 to the data reception device 20, for example, the maximum transfer rate of the communication line 30 is 28.8 kbps and the average transfer rate is 22 kbps. Even when the necessary data transfer rate (hereinafter simply referred to as the playback rate) is 32 kbps and real-time playback is not possible in the past, for example, the data transmitting device 10 can provide this music data in the low frequency range. By transferring the data to the data receiving device 20 separately for the data and the complementary data for the high frequency range, the reproduction rate of the outline data of the music data can be set to 16 kbps. Thereby, in the data transmission / reception system 1, since the transfer rate of the communication line 30 exceeds the reproduction rate of the outline data, the data reception device 20 reproduces the outline data, thereby reproducing the audio data at the time of real-time reproduction. Can be played continuously, and although the sound quality is not sufficient, the downloaded music can be monitored.
[0059]
Next, a flow of processing related to data transmission / reception performed between the data receiving device 20 and the data transmitting device 10 in the data transmission / reception system 1 will be described with reference to a flowchart shown in FIG. 5 and a time chart shown in FIG. .
[0060]
The data receiving device 20 on the user side makes a request comprising the data designation information and the user ID information by controlling the control unit 26 to perform a predetermined display on the monitor of the output unit 25 in step S1 after starting the control program. This is an input mode for generating information. Here, the user determines the genre, performer, title, and the like of the requested data by performing an input operation on the above-described data name regarding data such as music that the user desires. As a result, in the data receiving device 20, the data specifying information is generated by the control unit 26, and user ID information is generated from the user ID registered in advance. These pieces of information are not shown in the control unit 26 as request information. Once stored in memory. Then, when this storage is completed, the process proceeds to step S2.
[0061]
In step S <b> 2, the control unit 26 reads the generated request information from the memory and controls the modem 21 to transmit the request information to the data transmission device 10 via the communication line 30.
[0062]
The server-side data transmitting apparatus 10 that has received the request information causes the control unit 15 to control the data search processing unit 13 so that the corresponding data is searched from the hard disk array 12 based on the data designation information. Data retrieval processing is performed (step S3), and the retrieved data is read from the hard disk array 12.
[0063]
In the subsequent step S4, the control unit 15 of the data transmitting apparatus 10 performs the data so as to separate the data retrieved and read in step S3 into summary data and complementary data by the method of the first to fourth embodiments described above. Data separation processing is performed by controlling the separation unit 14.
[0064]
Further, in the subsequent step S5, the control unit 15 of the data transmitting apparatus 10 refers to the user ID information, and first receives the summary data for the data subjected to the separation processing via the communication line 30 on the user side. The data separation unit 14 and the modem 11 are controlled so as to be transferred to the device 20, and the control for storing the complementary data in the memory of the data separation unit 14 is performed.
[0065]
Then, the control unit 26 of the data receiving device 20 controls the modem 21 so as to receive the summary data transmitted from the data transmitting device 10 via the communication line 30, and the received summary data is transmitted to the data synthesizing unit 23. The reproduction process is performed so that the data synthesizing unit 23 is controlled so as to be stored in the memory and the summary data is output to the reproduction processing unit 24, and the above-described predetermined processing is performed on the summary data supplied from the data synthesis unit 23. The unit 24 is controlled (step S6). Thereby, in the data receiving device 20, as shown in (A) and (B) of FIG. ₀ Then, the above-described processes for receiving, reproducing, and storing the summary data are started. Here, in FIG. 6, (A) shows the processing contents of the data receiving apparatus 20 when the actual reproduction time of the summary data is shorter than the reception time of both the summary data and the supplementary data, and (B) shows the summary data. Represents the processing contents of the data receiving device 20 when the actual reproduction time is longer than the total reception time of both the summary data and the complementary data.
[0066]
In the data receiving device 20, this summary data is supplied to the output unit 25 as an analog reproduction signal, and in the case of the third embodiment, a mid-range audio output is output from the speaker of the output unit 25. Become.
[0067]
In this case, when storing the summary data, the control unit 26 may control the modem 21 and the HDD 22 so as to record the summary data received by the modem 21 on the hard disk.
[0068]
When the transmission of the summary data in step S5 is completed, the control unit 15 of the data transmission device 10 reads the complementary data stored in the memory of the data separation unit 14 and transmits it to the data reception device 20 and the data separation unit 14 and By controlling the modem 11, a complementary data transmission process is performed (step S7).
[0069]
And the control part 26 of the data receiver 20 which received this complementary data reads summary data from the memory of the data synthetic | combination part 23, and shows the time t shown to (A) and (B) of FIG. ₁ Then, the received supplementary data and the read summary data are combined to generate combined data (step S8). Further, the control unit 26 controls the data synthesizing unit 23 and the HDD 22 so as to supply the generated synthesized data to the HDD 22 and record it on the hard disk in the HDD 22 (step S9). When is finished, the process proceeds to step S10.
[0070]
In the subsequent step S10, the control unit 26 determines whether or not the outline data reproduction process has been completed. Here, when it is determined that YES, that is, the outline data reproduction process has been completed, the case is specifically as shown in FIG. 3A, and the composite data storage process has been completed. Time t _Three Since the reproduction processing of the summary data has already been completed in FIG. On the other hand, when it is determined NO, that is, when it is determined that the outline data reproduction process has not ended, it is specifically the case as shown in FIG. 6B, and the time at which the combined data storage process ends is completed. t ₂ This is a case where the actual reproduction time of the summary data has not yet ended. In such a case, the control unit 26 proceeds to step S11 in order to perform higher quality data reproduction.
[0071]
In step S11, the control unit 26 performs the time t shown in FIG. ₂ To the time t when the actual playback time of the summary data is completed _Three Until then, so-called high quality reproduction processing is performed by synthesizing and reproducing the summary data and the complementary data. As a high quality reproduction processing method, the HDD 22 is controlled to reproduce the synthesized data stored in the hard disk, or the complementary data is stored in the memory of the data synthesis unit 23 in advance, and the data synthesis unit 23 is controlled. Then, a method of synthesizing the summary data and the complementary data to generate synthesized data, and causing the reproduction processing unit 24 to output the generated synthesized data can be used.
[0072]
Thereby, in the data receiving device 20, this synthesized data is supplied to the output unit 25 as an analog reproduction signal, and the audio restored from the speaker of the output unit 25 to an original sound in which, for example, the low and high frequencies of popular music are combined. A signal is output. And the control part 26 is time t shown in (B) of FIG. 6 when this high quality reproduction | regeneration was completed. _Three Then, the series of processes described above is terminated.
[0073]
As described above, in the data transmission / reception system 1, since the data designated by the user is separated into the summary data and the complementary data, and this is transferred in the order of the summary data and the complementary data, the transmission side to the reception side Transfer rate to the receiver can be reduced, interruption of the sound reproduced on the receiving side, reproduction failure, etc. can be avoided, and the reliability of real-time reproduction can be greatly improved.
[0074]
Further, the data transmission / reception system 1 separates the data designated by the user into summary data and complementary data as described above, and transfers the data in the order of summary data and complementary data. It is also possible to easily construct a service such as free of charge as so-called sample data and charged for the transfer of complementary data. In this case, for example, with respect to the transfer of the complementary data, the data transmitting device 10 adds a predetermined lock data for prohibiting reproduction to the complementary data and transfers it to the data receiving device 20, and the data receiving device 20 The key data corresponding to the lock data is acquired by performing a procedure for the accounting process, and the complement data can be reproduced by comparing the lock data with the key data. .
[0075]
According to the data transmission / reception system 1, the data receiving device 20 can download the data to the hard disk while confirming the contents of the requested data while receiving the summary data. Cancellation can be easily performed in the middle of the download, and even if supplementary data is charged as described above, no adverse effects occur.
[0076]
In the above-described embodiments, one configuration example of the MOD system has been described. However, the present invention is not limited to this, and so-called multi-functions such as VOD, still image data, text data, program data, and the like. Of course, the present invention can be applied to a system that distributes any digital data related to media information.
[0077]
For example, when the present invention is applied to a system that distributes image data, the data separation unit 14 separates image data into outline data and supplement data. For example, the outline data is data for even rasters, and is supplemented. There is a method in which data is data for odd rasters. Further, as a method for separating image data, there is a method in which summary data is data for even frames and complementary data is data for odd frames. Furthermore, as a method for separating image data, there is a method in which summary data is data in a low frequency region and complementary data is data in a high frequency region. Furthermore, as a method for separating image data, there is a method in which summary data is monochrome image data and complementary data is color image data.
[0078]
Furthermore, in the above-described embodiment, the complementary data is collectively sent at a time. However, the present invention is not limited to this, and the complementary data may be sent in several times. That is, for example, when the present invention is applied to the above-described system for distributing image data, image data is assigned as summary data, and captions of the image data are assigned as complementary data, or the assignment is reversed. Thus, it is also possible to transfer supplementary data a plurality of times for one transfer of summary data. Also, a low frequency portion of music data performed by an artist is assigned as summary data, a high frequency portion of this music data is assigned as first complementary data, and image data of this artist's jacket photo is assigned as second complementary data. It is possible to construct various forms of services such as allocation and allocation of data relating to the artist's profile information, concert information, and the like as third complementary data.
[0079]
In the first embodiment, the L + R channel audio data is used as the summary data and the LR channel audio data is used as the supplement data. However, the LR channel audio data is used as the summary data, and the complement data is used. The data may be L + R channel audio data. Needless to say, the present invention is not limited to two channels but is applied to audio data of two or more channels.
[0080]
Further, in the second embodiment, the audio data of the even spectrum is used as the outline data and the audio data of the odd spectrum is used as the supplement data. Spectrum audio data may be used.
[0081]
Further, in the fourth embodiment, vocal audio data is used as summary data and karaoke audio data is used as supplementary data. However, karaoke audio data is used as summary data, and vocal audio data is used as supplementary data. It may be data.
[0082]
【The invention's effect】
As described above in detail, according to the present invention, from the information center, the designated program can be restored to the original program by synthesizing the outline data with which the outline of the entire program can be grasped and the outline data. And receiving the summary data and the supplementary data distributed in the order of the summary data and the supplementary data at the receiving means, combining the received summary data and the supplementary data, and based on the summary data The supplementary data transmitted with the lock data added from the information center is received by the receiving means, and a predetermined charging process is performed to correspond to the received lock data. The key data is acquired, and the complementary data can be reproduced by collating the lock data with the key data, The program comprises audio data, and the summary data and the complementary data distributed from the information center comprise an addition output of a plurality of channels of the audio data and a subtraction output of a plurality of channels of the audio data, The summary data and the supplementary data are Addition / subtraction processing to the original signal Since the original program is restored, it is possible to construct a service in which transfer of summary data is free as so-called sample data and charge is applied for transfer of complementary data. In addition, since it is possible to download to the hard disk while confirming the contents of the requested data while receiving the summary data, even if incorrect data is requested, it can be easily canceled in the middle of the download. Even if the supplementary data is charged as in FIG.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration example of a data transmission / reception system to which the present invention is applied.
FIG. 2 is a block diagram showing a specific configuration example of an encoding unit for high efficiency encoding employed in the data transmission / reception system.
FIG. 3 is a diagram illustrating frequency-time characteristics of orthogonal transform blocks in the high-efficiency encoding apparatus.
FIG. 4 is a block diagram illustrating a specific configuration example of a decoding unit for high efficiency encoding employed in the data transmission / reception system.
FIG. 5 is a flowchart showing a data distribution processing procedure in the data transmission / reception system.
FIG. 6 is a time chart showing the operation on the data receiving apparatus side in the data transmission / reception system, in which (A) shows data when the actual reproduction time of the summary data is shorter than the reception time of both the summary data and the complementary data. (B) shows the processing contents of the data receiving apparatus when the actual reproduction time of the summary data is longer than the total reception time of both the summary data and the complementary data.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Data transmission / reception system, 10 Data transmission apparatus, 20 Data reception apparatus, 30 Communication line, 11, 21 Modem, 12 Hard disk array, 13 Data search processing part, 14 Data separation part, 15 Control part, 22 HDD, 23 Data composition part 24 reproduction processing unit 25 output unit 26 control unit 27 operation input unit

Claims (4)

From the information center, the specified program is separated into summary data from which the overview of the entire program can be grasped and supplementary data that can be restored to the original program by combining with the above summary data, and delivered in the order of summary data and supplementary data A terminal device,
Receiving means for receiving summary data and supplementary data distributed from the information center;
Combining means for combining the summary data received by the receiving means and the complementary data;
Reproducing means for performing monitor reproduction based on at least the summary data among the separated data received,
The program comprises audio data, and the summary data and the complementary data distributed from the information center comprise an addition output of a plurality of channels of the audio data and a subtraction output of a plurality of channels of the audio data,
The complementary data transmitted with the lock data added from the information center is received by the receiving means, and the key data corresponding to the received lock data is obtained by applying a predetermined charging process, The complementary data can be reproduced by comparing the lock data with the key data, and the original program is restored to the original signal by adding / subtracting the summary data and the complementary data by the synthesizing means. A terminal device characterized by that.   2. The terminal device according to claim 1, wherein the supplementary data is transferred in a plurality of times with respect to one transfer of the summary data from the information center.   2. The terminal device according to claim 1, wherein the summary data continues to be monitored and reproduced even if downloading of the complementary data from the information center is started.   4. The terminal device according to claim 3, wherein the summary data is reproduced free of monitor.

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